PO.TB05.03 · 肿瘤生物学

Synergistic targeting of EP300/CBP and EYA co-activators collapses the rhabdomyosarcoma core regulatory circuit

海报缩略图:Synergistic targeting of EP300/CBP and EYA co-activators collapses the rhabdomyosarcoma core regulatory circuit
编号 3500 展板 15 时间 4/20 02:00–05:00 区域 Section 31 主讲 Brian Abraham, PhD
分会场 Pediatric Cancer Genomics and Epigenomics
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作者与单位

Annika Gustafson1, Stephanie Nance2, Berkley Gryder3, Noha A. Shendy2, Lars Wick1, Grace McKay-Corkum2, K. Elaine Ritter2, Stephen Connor Purdy1, Arthur R. Wolin1, Sheera R. Rosenbaum1, Sabateeshan Mathavarajah4, Nickerson A. Demelfi4, Yueyang Wang4, Yang Zhang2, Mark W. W. Zimmerman5, Anoop M. Kavirayani2, John Hardin1, Alexander LaVeck6, Xiang Wang6, Neekesh V. Dharia7, Andrew Hong8, Guillaume Kugener7, Jesse S. Boehm9, Jennifer Roth7, Javed Khan10, Francisca Vasquez7, Kristin B. Artinger11, Rui Zhao1, David M. Langenau12, Jun Qi5, Kimberly Stegmaier5, Heide L. Ford1, Adam D. Durbin2, Brian J. Abraham2

1University of Colorado Anschutz, Anschutz, CO,2St. Jude Children's Research Hospital, Memphis, TN,3Case Western Reserve University School of Medicine, Cleveland, OH,4Massachusetts General Hospital, Boston, MA,5Dana-Farber Cancer Institute, Boston, MA,6University of Colorado Boulder, Boulder, CO,7Broad Institute of MIT and Harvard, Cambridge, MA,8Emory University, Atlanta, GA,9Koch Inst. for Integrative Cancer Research at MIT, Cambridge, MA,10National Cancer Institute, Bethesda, MD,11University of Minnesota, Minneapolis, MN,12MGH/Harvard Medical School, Stoneham, MA

摘要 Abstract

Rhabdomyosarcoma (RMS) is a high-risk and lethal pediatric sarcoma that resembles developing skeletal muscle. RMS tumors have low mutation burdens, but these scant mutations often alter genes involved in transcriptional control. Transcriptional dysregulation is critical to RMS pathogenesis, supported by studies in both RMS tumors carrying mutationally derived chimeric transcription factors (“fusion positive (FP)”), or those without (“fusion negative” (FN)). However, mechanisms to selectively target dysregulated transcription in RMS remain outstanding. Here, we develop a novel approach targeting RMS transcription comprising simultaneous targeting of two distinctly acting transcriptional co-activators. We discover a common cell identity-controlling pan-RMS core regulatory circuit (CRC) composed of oncogenic and lineage-specific myogenic master transcription factors (mTFs). These mTFs are regulated by super-enhancers, and they co-bind genome-wide to control the malignant transcriptome of both FP- and FN-RMS. Using a super-enhancer-based reporter screen, we identify the EP300/CBP inhibitor A485 as a potent inhibitor of the pan-RMS CRC, though efficacy of this compound was limited by toxicity. To enhance on-target specificity, we identify the protein EYA2 as a co-factor that binds directly to SIX1, a member of the pan-RMS CRC and exploit a recently developed second-generation EYA1/2 tyrosine phosphatase inhibitor, LG1-34, to inactivate its function. While A485 and LG1-34 independently reduce mTF transcription and drive RMS cell death, in combination, these agents function synergistically to reduce RMS growth in vitro and in vivo. These results demonstrate that combined targeting of enhancer maintenance and CRC cofactors is a powerful strategy to suppress the RMS transcriptome and enforce RMS cell death.
利益披露 Disclosure
A. Gustafson, None.. S. Nance, None.. N. A. Shendy, None.. L. Wick, None.. G. McKay-Corkum, None.. K. E. Ritter, None.. S. Purdy, None.. A. R. Wolin, None.. S. R. Rosenbaum, None.. S. Mathavarajah, None.. N. A. Demelfi, None.. Y. Wang, None.. Y. Zhang, None. M. W. W. Zimmerman, Foghorn Therapeutics Employment. A. M. Kavirayani, None.. J. Hardin, None.. A. LaVeck, None.. X. Wang, None. N. V. Dharia, Genentech Employment. A. Hong, None.. G. Kugener, None.. J. Roth, None.. F. Vasquez, None.. K. B. Artinger, None.. R. Zhao, None.. H. L. Ford, None.. A. D. Durbin, None.. B. J. Abraham, None.

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